Explore quantum data structures for classical computers in this ACCU 2018 conference talk. Delve into the fundamental differences between classical and quantum computing, focusing on how quantum interference affects computation and software engineering strategies. Learn about the challenges of implementing quantum-inspired data structures on classical machines, including concepts like superposition, entanglement, and coherence. Examine C++ code examples illustrating quantum corollaries for classical computing idioms, and discuss how these concepts can broaden computational options for existing software engineering challenges. Gain insights into the potential applications of quantum-inspired approaches on current systems and consider new design paradigms for emerging hardware reliant on quantum effects.
A Quantum Data Structure For Classical Computers
Overview
Syllabus
Introduction
State
Access
Quantization
Quantum Jumps
Continuous Range
Data Objects
Digital vs Analog
Classical Assumptions
Max Planck
Compton Scattering
Mass Is Not Constant
Discrete
Indivisible
Quantum
Radix
Base
Quantum Interference
Destructive Mutation
High Complexity
Eigen States
Interference
Reading the volume
Quantum bits
Quantum memory requirements
Quantum supremacy
Limitations of classical systems
Quantum computers
Quantum computing
Planck
Schrodinger
Time
Quantum Lifecycle Setup
Contact Swap
Taught by
ACCU Conference
